Tandem Bond-Forming Reactions of 1-Alkynyl Ethers - Accounts of

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Tandem Bond-Forming Reactions of 1‑Alkynyl Ethers Thomas G. Minehan* Department of Chemistry and Biochemistry, California State University, Northridge, 18111 Nordhoff Street, Northridge, California 91330, United States

CONSPECTUS: Electron-rich alkynes, such as ynamines, ynamides, and ynol ethers, are functional groups that possess significant potential in organic chemistry for the formation of carbon−carbon bonds. While the synthetic utility of ynamides has recently been expanded considerably, 1-alkynyl ethers, which possess many of the reactivity features of ynamides, have traditionally been far less investigated because of concerns about their stability. Like ynamides, ynol ethers are relatively unhindered to approach by functional groups present in the same or different molecules because of their linear geometry, and they can potentially form up to four new bonds in a single transformation. Ynol ethers also possess unique reactivity features that make them complementary to ynamides. Research over the past decade has shown that ynol ethers formed in situ from stable precursors engage in a variety of useful carbon−carbon bond-forming processes. Upon formation at −78 °C, allyl alkynyl ethers undergo a rapid [3,3]-sigmatropic rearrangement to form allyl ketene intermediates, which may be trapped with alcohol or amine nucleophiles to form γ,δ-unsaturated carboxylic acid derivatives. The process is stereospecific, takes place in minutes at cryogenic temperatures, and affords products containing (quaternary) stereogenic carbon atoms. Trapping of the intermediate allyl ketene with carbonyl compounds, epoxides, or oxetanes instead leads to complex α-functionalized β-, γ-, or δ-lactones, respectively. [3,3]-Sigmatropic rearrangement of benzyl alkynyl ethers also takes place at temperatures ranging from −78 to 60 °C to afford substituted 2-indanones via intramolecular carbocyclization of the ketene intermediate. tert-Butyl alkynyl ethers containing pendant di- and trisubstituted alkenes and enol ethers are stable to chromatographic isolation and undergo a retro-ene/[2 + 2] cycloaddition reaction upon mild thermolysis (90 °C) to afford cis-fused cyclobutanones and donor−acceptor cyclobutanones in good to excellent yields and diastereoselectivities. This process, which takes place under neutral conditions and proceeds through an aldoketene intermediate, obviates the need to employ moisture-sensitive and/or unstable acid chlorides under basic conditions for intramolecular [2 + 2] cycloaddition reactions. Furthermore, Lewis acidcatalyzed intramolecular condensations of both ethyl and tert-butyl ynol ethers with tethered acetals efficiently provide protected five-, six-, and seven-membered cyclic Baylis−Hilman adducts. Metalated ethoxyacetylene can also participate in multiple bondforming reactions that avoid isolation of the alkynyl ether intermediate. Lewis acid-promoted tandem additions employing epoxides/oxetanes and carbonyl compounds give rise to (Z)-α-alkylidene and α-benzylidene lactones stereoselectively in high overall yields. Three new carbon−carbon bonds and a ring are formed in this atom-economical single-flask transformation, resulting in a significant increase in molecular complexity. This Account provides a detailed overview of these useful transformations with the intention of stimulating further interest in and research on ynol ethers and their application in organic synthesis.

1. INTRODUCTION The ynol ether functional group possesses a highly polarized triple bond, giving it heightened reactivity as both an electrophile (at C1) and as a nucleophile (at C2) (Figure 1).1 For example, it can be envisioned that sequential reactions of ynol ether A with an electrophile (El) and then a nucleophile (Nu) would give rise to enol ether B, which can rearrange to C or further react at C2 © XXXX American Chemical Society

with an electrophile (El′) and at C1 with a nucleophile (Nu′) to provide a complex substituted ether such as compound D or α-substituted carbonyl compound E. Thus, up to four new covalent bonds may be fashioned in this process, and the tethering of Received: February 27, 2016

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Accounts of Chemical Research

Figure 1. Reactivity of 1-alkynyl ethers.

Scheme 1. Claisen Rearrangement (1): Thermal7 (2) and Ireland−Claisen9 (3, 4) Variants

an electrophile−nucleophile pair would allow a carbocyclic or heterocyclic ring to be formed. Historically, synthetic chemists have not taken full advantage of this potential reactivity pattern of ynol ethers, especially with respect to carbon−carbon bond formation. Only recently has the utility of silyl ynol ethers in [2 + 2] cycloadditions37a and ring-expansion processes33 begun to be explored. Furthermore, while 1-alkynyl ethers have been commonly employed in (macro)lactone and lactam formation,2 transition-metal-catalyzed processes,3 and benzannulation reactions,37b concerns about the stability of ynol ethers have directed the attention of the synthetic community toward the ynamide functional group4 and ynolates.5 Over the past decade we have focused our attention on both the synthesis and reactivity of 1-alkynyl ethers and have discovered that this functional group indeed possesses important reactivity patterns that complement those available to ynamides. In this Account, we discuss our work on tandem bond-forming reactions of ynol ethers and highlight their utility in organic synthesis for the rapid buildup of molecular complexity.

Scheme 2. Allyl Alkynyl Ether Sigmatropy; Katzenellenbogen’s Study12

2. [3,3]-SIGMATROPIC REARRANGEMENT OF ALLYL ALKYNYL ETHERS The [3,3]-sigmatropic rearrangement of allyl vinyl ethers (the Claisen rearrangement) is a powerful method for the formation of carbon−carbon bonds.6 In this process, a C−O σ bond is broken and a C−C σ bond is formed in a highly stereospecific fashion; the concomitant exchange of a weaker alkene (CC) bond for a stronger carbonyl (CO) bond provides the thermodynamic driving force for the overall process. Uncatalyzed Claisen rearrangements take place under thermal conditions with temperatures typically in excess of 150 °C,7 with measured activation barriers in the range of 28−32 kcal/mol.8 The Ireland−Claisen rearrangement of allylic esters via their enolate or silyl enol ether forms is a particularly useful variant of the classic reaction that occurs at significantly lower temperatures (−78 to 60 °C) and with predictable and high diastereoselectivities based on control of the intermediate enol/enolate geometry (Scheme 1).9 We initially were interested in investigating whether allyl 1-alkynyl ethers would similarly participate in a Claisen-like [3,3]-sigmatropic process (Scheme 2). Once again, the exchange of a weaker CC bond for a stronger CO bond would provide the thermodynamic driving force for the rearrangement, with an allyl ketene being formed as the initial product. The allyl ketene could be trapped by reaction with an added nucleophile, giving rise to a γ,δ-unsaturated carbonyl compound. Although the early investigations of Arens10 and Schmid11 on the sigmatropy of benzyl alkynyl ethers (vide infra) along these lines were encouraging, evidence of the feasibility of this specific reaction manifold came from the work of Katzenellebogen,12

who showed that treatment of allyl bromovinyl ethers with sodamide in refluxing ammonia produced pent-4-enamides in good yields. The proposed mechanism involved base-mediated dehydrohalogenation to form the allyl alkynyl ether followed by [3,3]-sigmatropic rearrangement and ketene trapping with amide ion. Although the remarkable facility of this rearrangement at low temperature was noted, at the time no further efforts were made to study this process. The synthesis of 1-alkynyl ethers presented one of the first obstacles to studying the rearrangement reaction. As noted by Katzenellenbogen,12 all attempts to prepare allyl alkynyl ethers directly by reaction of metal allyloxides with haloacetylenes fail, giving only acetylene dimers. In 1987, Greene13 showed that 1,2-dichlorovinyl ethers could be transformed into lithioalkynyl ethers by treatment with 2 equiv of n-BuLi; protonation with methanol furnished terminal alkynyl ethers, while alkylation with iodoalkanes gave rise to substituted alkoxyacetylenes.14 In 2000, Bruckner showed that a similar treatment of 1,1-dichlorovinyl ethers also provides ynol ethers.15 Thus, we B

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Accounts of Chemical Research Scheme 3. Preparation and n-BuLi-Induced Rearrangement of Allyl 1,1-Dichlorovinyl Ethers

with glucal-3-O-dichlorovinyl ethers 7 and 9. Dibenzyl glucal derivative 7 rearranges smoothly to β-C-glycoside 8 in 65% yield upon exposure to n-BuLi at −78 °C followed by ethanol quench. However, conformationally restricted glucal-4,6-acetonide 9 gave none of the rearranged ester when subjected to the same conditions, producing only decomposition products when the reaction mixture was warmed to room temperature. Since the dichlorovinyl ether unit of 9 cannot access the axial conformation necessary to achieve close proximity of the reacting termini at C1 and C6′, these results provide evidence for the existence of a pathway involving a cyclic transition state. Our initially proposed mechanism for this transformation involved base-mediated formation of a lithioalkynyl ether followed by sigmatropic rearrangement and reaction of the allyl ketene intermediate with the quenching agent. One critical observation provided insight into the early stages of the reaction: treatment of allyl 1,1-dibromovinyl ethers with n-BuLi at −78 °C followed by methanol quench gave a 20:1) diastereoselectivity (compare 35b → 36b, 70% yield, dr = 2:1), perhaps indicating an interaction between the hydroxyl proton and the π systems of the ketene or alkene during the transition state for [2 + 2] cycloaddition. In this example, the process represents an advantage over other methods for ketene

Scheme 12. Thermal Ketene Generation/Intramolecular Trapping Reactions of Ynol Ethers

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Accounts of Chemical Research Scheme 13. Thermal Retro-Ene/[2 + 2] Cycloaddition of Alkene-Tethered Ynol Ethers

Scheme 14. Cycloadditions of Substrates Bearing Alcohols, Trisubstituted Alkenes, and Enol Ethers

compounds (e.g., 36b−d) and donor−acceptor cyclobutanones (36e−g) in good yields. The cyclobutanone products can be easily transformed into lactones by chemoselective oxidation with MCPBA to furnish synthetically useful cis-fused 5,5-ring systems such as 37g.

generation involving acid chlorides, since hydroxyl-bearing substrates would be prone to inter/intramolecular esterification reactions under basic conditions. Furthermore, both trisubstituted alkenes and enol ethers could be employed efficiently in the [2 + 2] cycloaddition reaction, furnishing fused tricyclic I

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Accounts of Chemical Research Scheme 15. Synthesis of Alkoxycycloalkene Carboxylates from Ynol Ether−Acetals

carboxylates that may undergo further stereoselective transformations such as allylic substitution or Michael addition reactions, allowing the introduction of carbon substituents β to the ester functional group.32 An intermolecular variant of this process using triisopropylsilyl ynol ethers and in situ-generated cyclic oxonium ions has recently been developed Zhao, Li, and Sun33 for the synthesis of medium- and large-ring lactones (Scheme 16).

The thermal retro-ene/intramolecular [2 + 2] cycloaddition reaction of ene−ynol ethers thus represents a practical and useful alternative to currently available methods for the synthesis of fused cyclobutanones.

5. INTRAMOLECULAR LEWIS ACID-CATALYZED YNOL ETHER−ACETAL CONDENSATION In an effort to extend the retro-ene/[2 + 2] cycloaddition reaction to the synthesis of β-lactones and lactams by thermolysis of carbonyl- and imine-tethered ynol ethers, it was discovered that attempted deprotection of the ynol ether−acetal precursors led to the formation of alkoxycycloalkene carboxylates instead of the desired carbonyl compounds.31 For example, treatment of acetal 38a with catalytic amounts of I2 in acetone gave methyl ester 39a in 45% yield; in a similar manner, treatment of 38a with 5 mol % Sc(OTf)3 in acetonitrile gave 39a in 78% yield (Scheme 15). Other effective Lewis acid promoters of this intramolecular condensation reaction were TMSOTf (CH2Cl2, −78 °C, 70% yield of 39a) and In(OTf)3 (CH3CN, rt, 50% yield of 39a). A variety of five-, six, and seven-membered alkoxycycloalkane carboxylates could be prepared efficiently from ethyl- or tert-butyl ynol ether−acetals using 5 mol % Sc(OTf)3 as a promoter in acetonitrile. A possible mechanistic pathway for this process might involve Lewis acid coordination of the acetal oxygen atom followed by ionization and ynol ether−oxonium ion metathesis. For tert-butyl ynol ether substrates, loss of isobutylene from the ensuing oxocarbenium ion would furnish the observed methyl ester product; for ethyl ynol ethers, SN2-like cleavage at the oxocarbenium methyl group would furnish ethyl ester products. This methodology allows the rapid preparation of complex 5,7- and 6,7-ring systems reminiscent of those present in sesquiterpene natural products. It affords protected hydroxycycloalkene

Scheme 16. Synthesis of Medium- and Large-Ring Lactones from Silyl Ynol Ethers

6. TANDEM LEWIS ACID-PROMOTED REACTIONS OF ETHOXYACETYLENE, EPOXIDES/OXETANES, AND CARBONYL COMPOUNDS α-Alkylidene, α-benzylidene, and α-methylene lactone moieties are found in many biologically active natural products possessing antitumor, antifungal, and antibacterial activities.34 These motifs have been constructed by the condensation of lactone enolates with carbonyl compounds,35a by transition-metal-mediated lactonizations,35b or by Wittig-type reactions of phosphonate anions/phosphorus ylides and carbonyl compounds.35c It was envisioned that with 1-alkynyl ethers, a one-pot procedure for the synthesis of α-alkylidene and α-benzylidene lactones could be J

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Accounts of Chemical Research Scheme 17. Synthesis of α-Alkylidene and α-Benzylidene Lactones

achieved using three separate Lewis acid-catalyzed reactions: an epoxide/oxetane ring opening with ethoxyacetylene, an ynol ether−carbonyl metathesis reaction, and a lactonization of a hydroxy ester. Indeed, it was found that BF3·OEt2 is an efficient promoter of all three reactions, and high yields of unsaturated lactone products could be obtained in a single-flask procedure.36 Combination of (ethoxyethynyl)lithium with epoxides or oxetanes in the presence of 1 equiv of BF3·OEt2 gave rise to an isolable intermediate hydroxy−ynol ether (cf. 42a, Scheme 17), which could be further combined with equimolar amounts of aldehyde or ketone and BF3·OEt2 to produce an acyclic α-alkylidene or α-benzylidene ester (vide infra, 43, Scheme 19); subsequent addition of methanol to the reaction mixture and stirring at room temperature gave rise to the expected lactone products 44 with virtually exclusive production of the (Z)-alkene stereoisomer. A variety of mono- and disubstituted epoxides and oxetanes participate in this process, as well as electron-rich and electrondeficient aryl aldehydes, hindered and unhindered aliphatic aldehydes, cyclic and acylic ketones, and unsaturated aldehydes. α-Methylene lactones could also be prepared in a two-step sequence involving reaction of hydroxy−ynol ether 42a with Eschenmoser’s salt followed by stirring with TFA in toluene to effect lactonization, producing 44o (Scheme 18). From a mechanistic standpoint, combination of metalated ynol ether 40·Li with 41a and BF3·OEt2 gives rise to intermediate

42a·BF3Li, which then participates in metathesis with the added equivalent of carbonyl compound activated by a second equivalent of BF3·OEt2 (Scheme 19). The E/Z mixture initially produced at the acyclic unsaturated ester stage then undergoes alkene E-to-Z isomerization and lactonization reactions facilitated by BF3·OEt2 and the Brønsted acid formed when methanol is introduced into the reaction medium. Alkene isomerization may take place either before or after lactonization: whereas compound 43a (reaction a) is isolated as a 2.2:1 mixture of Z and E alkene stereoisomers, indicating a fast lactonization process (facilitated by the gem-dimethyl effect) occurring prior to complete alkene isomerization, alcohol 43i (reaction b) is formed as the Z isomer exclusively as a result of a slower lactonization process, allowing complete alkene E-to-Z isomerization of the acyclic enoate to take place under the acidic reaction conditions. This tandem process accomplishes the formation of three carbon−carbon bonds and a ring in a single chemical transformation and stereoselectively affords (Z)-α-alkylidene and (Z)-α-benzylidene lactones. We are currently exploring the application of this concept to the synthesis of acyclic and cyclic Baylis−Hillman adducts by the tandem reaction of metalated ethoxyacetylene with sequentially added carbonyl compounds or dicarbonyl compounds in the presence of Lewis acid (Scheme 20).

7. CONCLUSION 1-Alkynyl ethers have been shown to participate in a variety of useful tandem bond-forming reactions that result in the construction of complex cyclic (lactone, cyclobutanone, indanone, alkoxycycloalkene carboxylate) and acyclic (γ,δ-unsaturated carboxylate) products that are useful as intermediates in organic synthesis. In addition, it may be envisioned that many of these products may be readily elaborated to provide natural substances of medicinal and biological import. It is thus hoped that this Account stimulates further interest in and research on the

Scheme 18. Formation of α-Methylene Lactones

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Accounts of Chemical Research Scheme 19. Mechanistic Hypothesis for the Lewis Acid-Promoted Tandem Reaction

Scheme 20. Synthesis of Baylis−Hillman Adducts by Ynol Ether−Carbonyl Tandem Reactions

applications of ynol ethers for carbon−carbon bond formation in natural product synthesis.

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development of new and efficient methods for carbon−carbon bond formation.

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AUTHOR INFORMATION

Corresponding Author

ACKNOWLEDGMENTS

This Account is dedicated to Professor Peter B. Dervan on the occasion of his 70th birthday. T.G.M. acknowledges the many contributions of students Aaron Christopher, Stephen Kelly, Dahniel Brandes, Juan Sosa, Vincent Tran, Kevin Ng, and Armen Tudjarian to the research on 1-alkynyl ethers described herein. T.G.M. also thanks Professor Dan Little (UCSB) for DFT calculations and Professor Roald Hoffmann (Cornell University) for insightful mechanistic discussions on the n-BuLi-induced rearrangement of allyl 1,1-dichlorovinyl ethers. We also gratefully acknowledge the National Institutes of Health (SC3 GM 096899-01), the National Science Foundation (CHE-1508070), and the donors of the American Chemical Society Petroleum Research Fund (53693-URI) for their generous support of this research.

*E-mail: [email protected]. Notes

The authors declare no competing financial interest. Biography Thomas G. Minehan earned his B.A. in Chemistry from Columbia University (1992) and his Ph.D. in Chemistry from Harvard University (1998), working under the direction of Professor Yoshito Kishi. He then moved to California Institute of Technology to work with Professor Peter Dervan. In 2001, Professor Minehan began his independent academic career at Harvey Mudd College. In 2004, he moved to California State University, Northridge, where he is currently Professor of Chemistry. Professor Minehan is a synthetic organic chemist whose research program focuses on natural product synthesis and the L

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DOI: 10.1021/acs.accounts.6b00107 Acc. Chem. Res. XXXX, XXX, XXX−XXX

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DOI: 10.1021/acs.accounts.6b00107 Acc. Chem. Res. XXXX, XXX, XXX−XXX